Magnetic Force Between Two Parallel Conductors

Parallel wires carrying current produce significant magnetic fields, which in turn produce significant forces on currents.

Learning Objective

Express the magnetic force felt by a pair of wires in a form of an equation

Key Points

The field (B₁) that that current (I₁) from a wire creates can be calculated as a function of current and wire separation (r): $B_1=\frac {\mu_0I_1}{2\pi r}$ μ₀ is a constant.
$F=IlB \sin \theta$ describes the magnetic force felt by a pair of wires. If they are parallel the equation is simplified as the sine function is 1.
The force felt between two parallel conductive wires is used to define the ampere—the standard unit of current.

Terms

magnetic field
A condition in the space around a magnet or electric current in which there is a detectable magnetic force, and where two magnetic poles are present.
current
The time rate of flow of electric charge.
ampere
A unit of electrical current; the standard base unit in the International System of Units. Abbreviation: amp. Symbol: A.

Full Text

Parallel wires carrying current produce significant magnetic fields, which in turn produce significant forces on currents. The force felt between the wires is used to define the the standard unit of current, know as an amphere.

In , the field (B₁) that I₁ creates can be calculated as a function of current and wire separation (r):

Magnetic fields and force exerted by parallel current-carrying wires.

Currents I1 and I2 flow in the same direction, separated by a distance of r.

$B_1=\frac {\mu_0I_1}{2\pi r}$

The field B₁ exerts a force on the wire containing I₂. In the figure, this force is denoted as F₂.

The force F₂ exerts on wire 2 can be calculated as:

$F_2=I_2lB_1 \sin \theta$

Given that the field is uniform along and perpendicular to wire 2, sin θ = sin 90 derees = 1. Thus the force simplifies to: F₂=I₂lB₁

According to Newton's Third Law (F₁=-F₂), the forces on the two wires will be equal in magnitude and opposite in direction, so to simply we can use F instead of F₂. Given that wires are often very long, it's often convenient to solve for force per unit length. Rearranging the previous equation and using the definition of B₁ gives:

$\frac {F}{l}=\frac {\mu_0I_1I_2}{2\pi r}$

If the currents are in the same direction, the force attracts the wires. If the currents are in opposite directions, the force repels the wires.

The force between current-carrying wires is used as part of the operational definition of the ampere. For parallel wires placed one meter away from one another, each carrying one ampere, the force per meter is:

$\frac {F}{l}=\frac{(4\pi \cdot 10^{-7} T \cdot m/A)(1A)^2}{(2\pi )(1m)}=2 \cdot 10^{-7}N/m$

The final units come from replacing T with 1N/(A×m).

Incidentally, this value is the basis of the operational definition of the ampere. This means that one ampere of current through two infinitely long parallel conductors (separated by one meter in empty space and free of any other magnetic fields) causes a force of 2×10^-7 N/m on each conductor.

[ edit ]

Prev Concept

Ampere's Law: Magnetic Field Due to a Long Straight Wire

Mass Spectrometer

Next Concept